Abstract: An aerial photographing image pickup method comprises a step of making a flying object fly meanderingly, a step of taking the image at each vertex where a direction is changed in the meandering flight, a step of extracting feature points from a common overlay portion of the images taken from at least three adjacent vertices, a step of determining two images of two vertices in the images as one set and acquiring positional information of the two vertices by a GPS device for each set regarding at least two sets, a step of performing photogrammetry of the measuring points corresponding to the feature points based on positional information and based on the feature points of the two images and a step of determining the feature points when the surveying results of the measuring points coincide with each other in at least the two sets as tie points for image combination.

Abstract: The taking-off and landing target instrument 2 to be used in an automatic taking-off and landing system, comprising a target 37 having as many light emitting elements 44 as required for displaying patterns and a target control unit 38 for controlling light emission of the light emitting elements, wherein the light emitting elements are provided on a taking-off and landing surface of the target and are arranged so that a target mark 43 having the center of pattern under all turned-on status is formed, and wherein the target control unit controls a light emission so as to display firstly all turned-on patterns where all of the light emitting elements are turned on, and next, so as to display the light emitting elements in a predetermined pattern.

Abstract: An omnidirectional image measuring instrument comprises a horizontal rotary table, a horizontal rotary driving unit capable of rotating the horizontal rotary table at a constant speed, an EDM device and an image pickup device provided on the horizontal rotary table, and a control device for synchronously controlling a distance measurement by the EDM device and an image pickup by the image pickup device.

Abstract: A liquid container for use in an inclination detector includes a container body containing liquid forming a free surface and having a circumferential wall in a spherical form, in which the circumferential wall is formed so that a center of the circumferential wall and a center of the free surface coincide with each other.

Abstract: A flight control system for a flying object comprises a flying object, a navigating means provided in the flying object, a position measuring unit 17, a flight control unit 18 for controlling the navigating means, and a main arithmetic control unit 19 for controlling the position measuring unit and the flight control unit, and in the flight control system for a flying object, the position measuring unit has a GPS device 23 for measuring a ground coordinate of the flying object and a vertical camera 13 for taking a digital image below the flying object and measures an altitude of the flying object based on images at two points taken by the vertical camera, on ground coordinates of the two points measured by the GPS device, and on a focal length of the vertical camera, and the main arithmetic control unit controls the navigating means via the flight control unit based on the measured altitude and makes the flying object fly at a predetermined altitude.

Abstract: The invention provides a wide-angle image pickup unit, comprising at least two cameras (4a and 4b) to take digital images, wherein the two cameras are arranged in such a manner that optical axes (11a and 11b) of the two cameras cross perpendicularly each other on a same plane and images of wide field angle ? with the crossing point O as a center enable to be acquired, and wherein parts of field angles of the two cameras are superimposed on each other and an overlapping portion is formed by the two images superimposed on each other, and stereoscopic measurement can be performed based on the two images of the overlapping portion.

Abstract: The invention provides a three-dimensional data preparing method, using image pickup units 8a and 8b to take an image of scenery in the surroundings and to acquire digital image data, comprising a step of continuously taking images of scenery in the surroundings by the image pickup unit while moving, a step of acquiring the images taken at predetermined time interval as images for measurement, a step of extracting a landmark from the image for measurement through pattern recognition by using the landmark as a template, a step of carrying out a matching of two adjacent images for measurement as time passes, and a step of obtaining three-dimensional coordinates of a point to take the image for measurement based on three-dimensional coordinates of a landmark of the image for measurement where three-dimensional coordinates of the landmark included at least in the first one image for measurement is already known.

Abstract: A laser surveying instrument comprising a light source unit having two or more light emission sources for emitting pulsed distance measuring lights with different wavelengths, a light projecting unit for projecting the pulsed distance measuring lights with the two or more wavelengths on an optical axis, and a deflection member provided on the optical axis, is disclosed. The deflection member has two or more reflection surfaces which reflect each wavelength of the pulsed distance measuring lights independently, thereby dividing the pulsed distance measuring lights for every wavelength, and deflecting each of the distance measuring lights toward an object to be measured. The instrument comprises a single photodetection element for receiving reflected distance measuring lights from the object to be measured. In the laser surveying instrument, a measurement of distance is performed for every pulsed distance measuring light based on a photodetection signal produced by the photodetection element.

Abstract: The invention provides an automatic taking-off and landing system, comprising a flying object and a taking-off and landing target, wherein the flying object has an image pickup device 21 for taking images found in downward direction, navigation means 4, 5, 6, 8, 9, 10 and 11, and a control unit for processing images acquired by the image pickup device and for controlling the navigation means, and wherein the control unit calculates a positional relation between the taking-off and landing target and the flying object based on the image of the taking-off and landing target as acquired by the image pickup device and controls taking-off and landing operations of the flying object based on a result of the calculation.

Abstract: The invention provides a measuring device, comprising a distance measuring unit 8 for performing distance measurement on a measuring point by projecting a distance measuring light and by receiving a reflected distance measuring light from the measuring point, an image pickup unit 7 for acquiring a digital image of a measurement range, a distance measuring optical axis deflecting unit 16 for deflecting a distance measuring optical axis of the distance measuring light, an angle measuring unit 9 for measuring an angle of the distance measuring optical axis, an image processing unit 14 for extracting the measuring point through image processing of the digital image, and a control arithmetic unit 21, wherein the control arithmetic unit detects an angle of the measuring point on the digital image, controls the distance measuring optical axis deflecting unit based on the detected angle, directs the distance measuring optical axis toward the measuring point one after another and measures a distance to the measuring p

Abstract: The present invention provides a measuring device, comprising a light source unit 2 for projecting a pulsed distance measuring light 10 toward an object to be measured, a projecting light optical system 3 for projecting the pulsed distance measuring light emitted from the light source unit on the object to be measured, a light receiving optical system 4 for receiving a reflected pulsed distance measuring light 10? from the object to be measured, a light receiving part 6 having a single photodetector 12 for detecting the reflected pulsed distance measuring light as received, and a control unit 7 for measuring a distance by measuring time from light emission of the pulsed distance measuring light to receipt of the reflected pulsed distance measuring light based on a detection signal from the photodetector, wherein the light source unit has a plurality of light emitting sources 8 arranged in a known relation with respect to an optical axis of the projecting light optical system, and a driving unit 9 for driving

Abstract: The present invention provides an electron microscope device 1, comprising a scanning electron microscope 2 and an optical microscope 3, wherein the scanning electron microscope has scanning means 10 for scanning an electron beam and an electron detector 12 for detecting electrons issued from a specimen 8 scanned by the electron beam, and the scanning electron microscope acquires a scanning electron image based on a detection result from the electron detector, wherein the optical microscope projects an illumination light to the specimen, receives a reflection light from the specimen and acquires an optical image, and wherein an optical axis 7 of the scanning electron microscope crosses an optical axis 6 of the optical microscope at a point of observation of the specimen, wherein the scanning means projects the electron beam for scanning with a scanning width wider than a width of a scanning area, the optical microscope projects an illumination light and acquires an optical image in an overrunning portion wher

Abstract: A 3-dimensional data preparing method, comprising a first step of continuously taking digital images when moving from a first known point, via a second known point, to a third unknown point, a second step of generating tracking points from an image acquired at the first point, and sequentially specifying the tracking points on the continuously acquired images, a third step of obtaining 3-dimensional data of the tracking points based on the first and second points, a fourth step of sequentially obtaining a position of the third point, based on the orientation and the position data of the tracking point, a fifth step of obtaining position data of an image based on the first and second points, and a sixth step of sequentially obtaining position data of images from the orientation of the images at the second and third points and from the position data at those points.

Abstract: The present invention provides a surveying device, which comprises rotators 53, 56 and 61 for deflecting a distance measuring light in horizontal direction and for projecting the distance measuring light in rotary irradiation, at least one extension member 62 for increasing a spreading angle in vertical direction of the distance measuring light, and a means for attaching or detaching the extension member so that the extension member can be inserted and removed to or from a distance measuring optical axis.

Abstract: The invention provides a laser scanner 1 for performing multi-point measurement by projecting a pulsed beam 12 over total circumference for scanning, comprising a main unit 3 and a rotating unit 4 rotatably mounted on the main unit, wherein the rotating unit has a deflection member 15 for projecting the pulsed beams by deflecting the beams perpendicularly to center axis of the rotating unit, the main unit comprises a plurality of light emitting sources 11 disposed in two-dimensional positions and used for emitting a plurality of pulsed beams, an optical system 6 for projecting and receiving the pulsed beams, a rotation angle detecting unit 19 for detecting a horizontal rotation angle of the rotating unit, a plurality of photodetectors 8 for receiving a reflection light 12? from an object via the deflection member and being disposed respectively at positions conjugate to the light emitting sources, a distance measuring unit 9 for measuring a distance based on a photodetection signal from the photodetector, and

Abstract: The present invention provides a GPS-installed all-azimuth camera, comprising at least a pair of GPS antennas (29a and 29b) disposed on up and down in parallel to each other, a plurality of cameras (28a-28f) which are disposed on a plane running in parallel to the GPS antennas and are capable of obtaining images in all azimuths, and a case (27) for accommodating the cameras and the GPS antennas, wherein a reference position of the GPS antennas is concurred with an image reference position of the cameras.

Abstract: An electro-optical distance measuring device having a photodetection unit comprising a plurality of pixels arranged in a predetermined arrangement is disclosed. A signal processing unit has a storage unit for storing the detection result in correspondence with each of the pixels, wherein the signal processing control unit sequentially changes a position of the division for every cycle wave at which the photodetection amount is detected and continues detections until a detected range becomes at least one cycle or more. The arithmetic processing unit calculates a waveform for at least one cycle stored in the storage unit for each pixel, obtains a phase difference of the waveform with respect to the irradiated distance measuring light, and calculates the distance based on the phase difference.

Abstract: The present invention provides a surveying device, which comprises a light source for emitting a distance measuring light 6, an elevation rotary mirror 56 for deflecting said distance measuring light in a direction toward an object to be measured, a high-speed deflection mirror 62 for deflecting said distance measuring light at a speed higher than said elevation rotary mirror, a distance measuring light projecting unit for projecting said distance measuring light, and an arithmetic control unit for controlling driving of said high-speed deflection mirror and said elevation rotary mirror.

Abstract: In measuring a certain time lag between generations of two pulse signals, a time lag measuring device prevents errors in measurement results even with an error in two reference signals for measuring the time lag. The device measures a time lag between a start signal M1 and a stop signal M2 and includes a reference signal generating section 41 generating two reference signals S1, S2 having a phase difference ?/2, and an amplitude detecting section 42 detects amplitudes A11, A12 and A21, A22 of the reference signals S1, S2 at generation timings for the start signal M1 and the stop signal M2, a phase difference detecting section 43 calculating a phase _ of the reference signals S according to each set of the amplitudes (A11, A12) and (A21, A22), and a correcting section 46 correcting the calculated phase using correction data for error correction in the reference signals S1, S2.

Abstract: In measuring a certain time lag between generations of two pulse signals, a time lag measuring device prevents errors in measurement results even with an error in two reference signals for measuring the time lag. The device measures a time lag between a start signal M1 and a stop signal M2 and includes a reference signal generating section 41 generating two reference signals S1, S2 having a phase difference ?/2, and an amplitude detecting section 42 detects amplitudes A11, A12 and A21, A22 of the reference signals S1, S2 at generation timings for the start signal M1 and the stop signal M2, a phase difference detecting section 43 calculating a phase _ of the reference signals S according to each set of the amplitudes (A11, A12) and (A21, A22), and a correcting section 46 correcting the calculated phase using correction data for error correction in the reference signals S1, S2.